Age-related changes in insulin receptor mRNA and protein expression in genetically obese Zucker rats.

AIM: The mechanisms underlying the age-related decrease in insulin-receptor (IR) binding in genetically obese Zucker rats are not well understood. For this reason, the present study analyzed the expression of IR mRNA and protein in selected tissues from 1- to 4-month-old obese (fa/fa) Zucker rats and lean (Fa/-) age-matched controls. METHODS: The following parameters were evaluated: (1) IR mRNA level, and proportion of isotypes A (exon 11-) and B (exon 11+) of IR mRNA in liver, brain and kidney; (2) level, molecular size and tyrosine phosphorylation of IR-beta subunit in liver subcellular fractions; and (3) stability of liver IR based on sensitivity in vivo of insulin-binding activity and IR-beta levels in response to tunicamycin, a glycosylation inhibitor. RESULTS: At one month, IR mRNA level was increased in liver and brain, but decreased in kidneys and, at four months, both mRNA level and isotype B proportion were decreased in liver. From age two months, the following changes in liver IR protein expression were observed: (1) decreased IR-beta level in whole homogenates, but increased IR-beta levels in endosomal fractions; (2) increased IR-beta tyrosine phosphorylation; and (3) at four months, increased levels of both intact IR-beta (95 kDa) and IR-beta fragments (72 and 52 kDa) in lysosomal fractions, along with decreased stability in vivo of the IR. CONCLUSION: These data show that obese Zucker rats display age-related alterations of IR gene expression at both pre- and post-translational stages and, in particular, increased endocytosis and degradation of IR protein.

Endosomal proteolysis of internalised [ArgA0]-human insulin at neutral pH generates the mature insulin peptide in rat liver in vivo.

AIMS/HYPOTHESIS: A proteolysis study of human monoarginyl-insulin ([Arg(A0)]-HI) and diarginyl-insulin ([Arg(B31)-Arg(B32)]-HI) within hepatic endosomes was undertaken to determine whether the endosomal compartment represents a physiological site for the removal of Arg residues and conversion of Arg-extended insulins into fully processed human insulin. METHODS: The metabolic fate of arginyl-insulins has been studied using the in situ rat liver model system following ligand administration to rats and cell-free hepatic endosomes. RESULTS: While the kinetics of insulin receptor endocytosis after the administration of arginyl-insulins were similar to those observed using human insulin, a more prolonged concentration of endosomal insulin receptor was observed in response to [Arg(A0)]-HI. [Arg(A0)]-HI induced a marked increase in the phosphotyrosine content of endosomal insulin receptor, coinciding with a more sustained endosomal association of growth factor receptor-bound protein 14 (GRB14), and a higher and prolonged activation of mitogen-activated protein kinase pathways. At acidic pH, the endosomal cathepsin D rapidly degraded insulin peptides with similar binding affinity, and generated comparable intermediates for both arginyl-insulins without affecting amino and carboxyl arginyl-peptide bonds. At neutral pH, hepatic endosomes fully processed [Arg(A0)]-HI into mature human insulin while no conversion was observed with [Arg(B31)-Arg(B32)]-HI. The neutral endosomal Arg-convertase was sensitive to bestatin, immunologically distinct from insulin-degrading enzyme, nardilysin or furin, and was potentially related to aminopeptidase-B-type enzyme. CONCLUSIONS/INTERPRETATION: The data describe a unique processing pathway for the endosomal proteolysis of [Arg(A0)]-HI which involves the removal of Arg(A0) and subsequent generation of mature human insulin through an uncovered neutral Arg-aminopeptidase activity. The endosomal conversion of [Arg(A0)]-HI into human insulin might extend the insulin receptor signalling at this locus.

Glucagon receptors.

Glucagon is a pancreatic peptide hormone that, as a counterregulatory hormone for insulin, stimulates glucose release by the liver and maintains glucose homeostasis. First described as a glucagon binding entity functionally linked to adenylyl cyclase, the glucagon receptor is a member of the family B receptors within the G protein coupled superfamily of seven transmembrane-spanning receptors. During the past decade, considerable progress has been made in the identification of the molecular determinants of the glucagon receptor that are important for ligand binding and signal transduction, in the development of glucagon analogs and of nonpeptide small molecules acting as receptor antagonists, and in the characterization of the mechanisms involved in the regulation of expression of the glucagon receptor gene. In the present review, the current knowledge of glucagon receptor structure, function and expression is described, with emphasis on the metabolic fate of glucagon and on the endocytosis and cell itinerary of both ligand and receptor.

Processing of the insulin-like growth factor-II-mannose 6-phosphate receptor in isolated liver subcellular fractions.

A truncated, soluble form of the insulin-like growth factor-II-mannose 6-phosphate (IGF-II-M6P) receptor has been identified in serum and shown to be released from cultured tissues and cells, liver being the main contributor to serum receptor in adult rats. In the present study, the processing of the IGF-II-M6P receptor has been characterized in isolated liver subcellular fractions using ligand binding, affinity crosslinking, and Western immunoblotting techniques. The receptor in plasma membrane fractions differed from that in Golgi-endosomal fractions by: (i) a lower molecular size upon reducing polyacrylamide gel electrophoresis (245 vs. 255 kDa); (ii) a less tight membrane association as judged upon extractibility by NaCI; and (iii) the inability to recognize antibody anti-22C, directed against the cytoplasmic domain of the receptor. Incubation of cell fractions at 30 degrees C led to a pH- and time-dependent release of the receptor into the medium. The pH optimum for release was 5.5 in the Golgi-endosomal fraction and 7.5 in plasma membrane fractions; at this pH, approximately 2% and 20%-30% of total receptors were released per hour, respectively. Receptor release was inhibited in a dose-dependent manner by aprotinin, benzamidine, and leupeptin in the Golgi-endosomal fraction, and by 1,10 phenanthroline in plasma membrane fractions, although high concentrations were required for inhibition. The receptor released from Golgi-endosomes showed a 5-10 kDa reduction in size and a loss of ability to recognize antibody anti-22C, but that released from plasma membranes showed little or no changes in size. We conclude that soluble, carboxy-terminally truncated forms of the IGF-II-M6P receptor are generated from the intact receptor in isolated Golgi-endosomal and plasma membrane fractions. However, receptor processing in these fractions exhibits different properties, suggesting the involvement of different proteases.

Characterization of an in vivo hormonally regulated phosphodiesterase 3 (PDE3) associated with a liver Golgi-endosomal fraction.

The biochemical properties of an in vivo hormonally regulated low Km cAMP phosphodiesterase (PDE) activity associated with a liver Golgi-endosomal (GE) fraction have been characterized. DEAE-Sephacel chromatography of a GE fraction solubilized by a lysosomal extract resulted in the sequential elution of three peaks of activity (numbered I, II, and III), while ion-exchange HPLC resolved five peaks of activity (numbered 1, 2, 3, 4, and 5). Based on the sensitivity of the eluted activity to cGMP and selected phosphodiesterase inhibitors, two phosphodiesterase isoforms were resolved: a cGMP-stimulated and EHNA-inhibited PDE2, eluted in DEAE-Sephacel peak I and HPLC peak 2 and a cGMP-, a cilostamide-, and ICI 118233-inhibited PDE3, eluted in DEAE-Sephacel peak III and HPLC peaks 3, 4, and 5. GE fractions isolated after acute treatments with insulin, tetraiodoglucagon, and growth hormone displayed an increase in phosphodiesterase activity relative to saline-injected controls, as did GE fractions from genetically obese and hyperinsulinemic rats relative to lean littermates. In all experimental rats, an increase in PDE3 activity associated with DEAE-Sephacel peak III and HPLC peaks 4 and 5 was observed relative to control animals. Furthermore, in genetically obese Zucker rats, an increase in the sensitivity of PDE activity to cilostamide and in the amount of PDE activity immunoprecipitated by an antibody to adipose tissue PDE3 was observed relative to lean littermates. These results extend earlier studies on isolated hepatocytes and show that liver PDE3 is the main if not sole PDE isoform activated by insulin, glucagon, and growth hormone in vivo.

Insulin-induced redistribution of the insulin-like growth factor II/mannose 6-phosphate receptor in intact rat liver.

The ability of acute insulin treatment to elicit a redistribution of the liver insulin-like growth factor-II/ mannose 6-phosphate (IGF-II/M6P) receptor has been studied in rats, using cell fractionation. Injection of insulin (0.4-50 microg) led to a time- and dose-dependent decrease in IGF-II binding activity in Golgi-endosomal (GE) fractions, along with an increase in activity in the plasma membrane (PM) fraction; only receptor number was affected. Quantitative subfractionation of the microsomal fraction on sucrose density gradients showed that IGF-II binding activity distributed similarly to galactosyltransferase (a Golgi marker), at slightly higher densities than in vivo internalized (125)I-insulin, and at lower densities than 5' nucleotidase and alkaline phosphodiesterase (two plasma membrane markers). Insulin treatment led to a slight time-dependent and reversible shift of IGF-II binding activity toward higher densities. Subfractionation of the GE fraction on Percoll gradients showed that IGF-II binding activity was broadly distributed, with about 60% at low densities coinciding with galactosyltransferase and early internalized (125)I-insulin and with 40% at high densities in the region of late internalized (125)I-insulin. Insulin treatment caused a time-dependent and reversible shift of the distribution of IGF-II binding activity toward low densities. On SDS-PAGE, the size of the affinity-labeled IGF-II/M6P receptor was comparable in GE and PM fractions (about 255 kDa), but on Western blots receptor size was slightly lower in the latter (245 kDa) than in the former (255 kDa). Insulin treatment did not affect the size, but modified the abundance of the IGF-II/M6P receptor in a manner similar to that of IGF-II binding. In vivo chloroquine treatment fully suppressed the changes in IGF-II binding activity in liver GE and PM fractions observed in insulin-treated rats. We conclude that insulin elicits a time-dependent and reversible redistribution of liver IGF-II receptors from Golgi elements and endosomes to the plasma membrane, presumably via early endosomes.

Activation of a cGMP-stimulated cAMP phosphodiesterase by protein kinase C in a liver Golgi-endosomal fraction.

The ability of Ca2+/phospholipid-dependent protein kinase (protein kinase C, PKC) to stimulate cAMP phosphodiesterase (PDE) activity in a liver Golgi-endosomal (GE) fraction was examined in vivo and in a cell-free system. Injection into rats of 4 beta-phorbol 12-myristate 13-acetate, a known activator of PKC, caused a rapid and marked increase in PKC activity (+325% at 10 min) in the GE fraction, along with an increase in the abundance of the PKC alpha-isoform as seen on Western immunoblots. Concurrently, 4 beta-phorbol 12-myristate 13-acetate treatment caused a time-dependent increase in cAMP PDE activity in the GE fraction (96% at 30 min). Addition of the catalytic subunit of protein kinase A (PKA) to GE fractions from control and 4 beta-phorbol 12-myristate 13-acetate-treated rats led to a comparable increase (130-150%) in PDE activity, suggesting that PKA is probably not involved in the in-vivo effect of 4 beta-phorbol 12-myristate 13-acetate. In contrast, addition of purified PKC increased (twofold) PDE activity in GE fractions from control rats but affected only slightly the activity in GE fractions from 4 beta-phorbol 12-myristate 13-acetate-treated rats. About 50% of the Triton-X-100-solubilized cAMP PDE activity in the GE fraction was immunoprecipitated with an anti-PDE3 antibody. On DEAE-Sephacel chromatography, three peaks of PDE were sequentially eluted: one early peak, which was stimulated by cGMP and inhibited by erythro-9 (2-hydroxy-3-nonyl) adenine (EHNA); a selective inhibitor of type 2 PDEs; and two retarded peaks of activity, which were potently inhibited by cGMP and cilostamide, an inhibitor of type 3 PDEs. Further characterization of peak I by HPLC resolved a major peak which was activated (threefold) by 5 microM cGMP and inhibited (87%) by 25 microM EHNA, and a minor peak which was insensitive to EHNA and cilostamide. 4 beta-Phorbol 12-myristate 13-acetate treatment caused a selective increase (2.5-fold) in the activity associated with DEAE-Sephacel peak I, without changing the K(m) value. These results suggest that PKC selectively activates a PDE2, cGMP-stimulated isoform in the GE fraction.

Treatment of streptozotocin-induced diabetic rats with vanadate and phlorizin prevents the over-expression of the liver insulin receptor gene.

Administration of vanadate, an insulinomimetic agent, has been shown to normalize the increased number of insulin receptors in the liver of streptozotocin-induced diabetic rats. In the present study, the effects of vanadate on various steps of expression of the liver insulin receptor gene in diabetic rats have been analyzed and compared with those of phlorizin, a glucopenic drug devoid of insulinomimetic properties. Livers of rats killed 23 days after streptozotocin injection showed a 30-40% increase in the number of cell surface and intracellular insulin receptors, a 50-90% increase in the levels of 9.5 and 7.5 kb insulin receptor mRNA species, and a 20% decrease in the relative abundance of the A (exon 11-) insulin receptor mRNA isotype. Daily administration of vanadate or phlorizin from day 5 to day 23 prevented the increase in insulin receptor number and mRNA level, and vanadate treatment also normalized receptor mRNA isotype expression. Unlike observations in vivo, vanadate and phlorizin differentially affected the expression of the insulin receptor gene in Fao hepatoma cells. Vanadate treatment (0.5 mmol/l for 4 h) decreased the levels of the 9.5 and 7.5 kb insulin receptor transcripts by at least twofold, without affecting the relative abundance of the A insulin receptor mRNA isotype. In contrast, phlorizin treatment (5 mmol/l for 4 h) slightly increased or did not affect the levels of the 9.5 and 7.5 kb insulin receptor transcripts respectively, and increased by twofold the relative expression of the A insulin receptor mRNA isotype. It is suggested that, although mediated in part by a reversal of hyperglycemia, normalization of liver insulin receptor gene expression by vanadate treatment in diabetic rats may also involve a direct inhibitory effect of this drug on gene expression.

Longitudinal study of tissue- and subunit-specific obesity-induced regulation of the pyruvate dehydrogenase complex.

The tissue-specific expression of the mitochondrial pyruvate dehydrogenase complex (PDHc) has been studied in an animal model of obesity with hyperinsulinemia, the obese (fa/fa) Zucker rat. Liver and heart were obtained from 4 and 8 week-old obese rats and age-matched lean animals, and in each tissue the following parameters were analyzed: (1) total activity of the mitochondrial PDHc; (2) abundance of the mitochondrial PDHc subunits on Western blots; and (3) abundance of the E1alpha and E1beta subunit mRNAs on Northern blots and semi-quantitative RT-PCR. Regardless of age, obese rats showed an increase in liver total PDHc activity and a coordinate increase in liver E1alpha and E1beta PDHc subunit abundance. At 4 weeks, obese rats also showed an increase in liver PDH E1alpha mRNA level, but regardless of age E1beta mRNA level was unchanged. In contrast, neither total PDHc activity nor the concentration of its protein subunits were increased in heart of obese rats. Thus, obese Zucker rats display a liver-specific early increase in PDHc which results from a selective up-regulation of the E1alpha gene expression.

Endosome-lysosome transfer of insulin and glucagon in a liver cell-free system.

The endosome-lysosome transfer of in vivo internalized insulin and glucagon has been studied in a rat liver cell-free system and compared to that of galactosylated bovine serum albumin (GalBSA), a ligand of the asialoglycoprotein receptor. Density-gradient analysis of a postmitochondrial supernatant isolated 8 min after injection of [125I]iodoinsulin showed that the membrane-associated radioactivity (55% of the total) migrated as a single peak at the position of galactosyltransferase, a Golgi marker (1.08-1.10 g/ml). After incubation at 37 degrees C in the presence of ATP, an additional peak of radioactivity (12%) was detected at the position of acid phosphatase, a lysosomal marker (1.12-1.14 g/ml). No such peak was observed in a lysosome-depleted fraction. An ATP-dependent conversion of [125I]iodoinsulin to trichloroacetic-acid-soluble products occurred during incubation (20%) but this was unaffected by lysosome depletion. Gel-filtration and HPLC analysis of acid extracts of gradient fractions isolated after injection of [125I]iodoinsulins selectively labeled at tyrosine residues A14 or B26 revealed the presence of components which differed from intact iodoinsulins by size and/or hydrophobicity. Low molecular-mass components were less abundant and, conversely, intact iodoinsulin and/or high molecular-mass components more abundant in lysosomal fractions than in endosomal fractions. In vivo internalized [125I]iodoglucagon and [125I]iodogalBSA underwent a greater lysosomal transfer (17-21%) and lesser degradation (8-11%) than [125I]iodoinsulin. Glycyl-L-phenylalanine 2-naphtylamide and methionine O-methyl ester, two lysosome-disrupting enzyme substrates, partially released the radioactivity associated with lysosomal fractions (GalBSA > insulin = glucagon) but caused little or no release of that associated with endosomal fractions. Analysis of the alpha and beta subunits of the insulin receptor by cross-linking to [125I]iodoinsulin and Western immunoblotting, respectively, revealed a partial lysosomal transfer of these subunits during endosome-lysosome interaction. We conclude that an endosome-lysosome transfer of insulin and glucagon occurs in a liver cell-free system and suggest that the low recovery of these peptides in lysosomal fractions in vivo results from their rapid degradation within endosomes.

Familial hyperproinsulinaemia due to a mutation substituting histidine for arginine at position 65 in proinsulin: identification of the mutation by restriction enzyme mapping.

UNLABELLED: Familial hyperproinsulinaemia is a rare genetic disorder characterized by point mutations in the insulin gene which impair the conversion of proinsulin to insulin. We report here three members of a two-generation Caucasian family in whom this syndrome was identified by unexplained hyperinsulinism associated with normal glucose tolerance and normal insulin sensitivity. Plasma insulin immunoreactivity showed a reduced affinity for the insulin receptor and eluted mainly, on Biogel chromatography, at the position of proinsulin. Analysis of the PCR-amplified insulin gene by restriction enzyme mapping revealed a new recognition site for the enzyme Nla III, indicating a Arg65 to His mutation. Sequence analysis of exon 3 confirmed this mutation in one allele of the gene. CONCLUSION: This study reports a two-generation European-Caucasian family with hyperproinsulinaemia due to a substitution of His for Arg at position 65 in proinsulin, the seventh now identified worldwide and the second from Europe. The mutation generated a new restriction site on the insulin gene suggesting the usefulness of restriction enzyme mapping as a screening procedure.

Increased expression of liver PKC alpha in hypoinsulinemic diabetic rats: a post-translational effect.

Ca2+-dependent protein kinase C (cPKC) activity and expression have been studied in livers from hypoinsulinemic streptozotocin (STZ)-induced diabetic and untreated control rats. In diabetic rats, cPKC activity was slightly decreased in liver total particulate and nuclear fractions but was unchanged in mitochondrial-lysosomal, microsomal and cytosolic fractions. On Western immunoblot analysis, PKC alpha was identified as two distinct proteins of 90 and 81 kDa. In diabetic rats, the abundance of the 90 kDa protein was increased in most subcellular fractions with a maximum in the cytosolic and microsomal fractions (180%) but that of the 81 kDa protein was unchanged. PKC beta2 was detected as a single 81 kDa protein in cytosolic and microsomal fractions with unchanged levels in diabetic rats. Liver PKC alpha mRNA levels as measured by reverse transcription and competitive PCR amplification were similar in diabetic and control rats. The increased expression of PKC alpha protein in diabetic rats was reversed by insulin but not by phlorizin, suggesting that it did not result from hyperglycemia. We conclude that STZ-induced diabetes induces the expression of a biologically inactive form of PKC alpha which differs from active PKC alpha by an undefined post-translational modification, possibly an increase in phosphorylation state.

Vanadate, but not insulin, inhibits insulin receptor gene expression in rat hepatoma cells.

Insulin and vanadate treatments have recently been shown to reverse the overexpression of the hepatic insulin receptor (IR) gene in streptozotocin-induced diabetic rats. To better understand the mechanisms underlying these effects, the abilities of insulin and vanadate to affect IR gene expression have been comparatively examined in Fao hepatoma cells, an insulin-responsive cell line. Exposure of Fao cells to insulin (1 microM) or vanadate (500 microM) for 24 h led to a 2-fold decrease in IR number in total cellular membranes. Insulin treatment did not affect IR messenger RNA (mRNA) level regardless of time of exposure and concentration. In contrast, vanadate treatment caused a time- and dose-dependent decrease in IR mRNA level, which was maximal (4-fold change) after a 24-h exposure to 500 microM vanadate and was fully reversible. Insulin treatment increased from 28 to 39% the relative expression of isotype A IR mRNA, but vanadate treatment did not significantly affect this parameter. Vanadate treatment did not modify mRNA half-life (3.5 h) in 5, 6 dichlorobenzimidazole riboside-treated cells but decreased by 4-fold the transcriptional activity of the IR gene. These data show for the first time that, although both insulin and vanadate decrease total cellular IR number in Fao cells, only vanadate decreases IR mRNA level. It does so by inhibiting transcription of the IR gene, suggesting an action on the gene promoter which could be mediated by changes in the level of expression and/or of phosphorylation of trans-acting factors.

Expression of the hepatic insulin receptor gene in the rat during postnatal development.

Changes in the expression of the liver insulin receptor are known to occur in the rat during postnatal development. To assess whether such changes occur at the level of gene expression, steady-state levels of insulin receptor mRNA and transcription rates of the receptor gene have been measured in livers of rats from birth (1 day) to adulthood (60 days). Northern blot analysis of liver RNA revealed two major insulin receptor mRNA species of 9.5 and 7.5 kb. When normalized to beta actin mRNA, insulin receptor mRNA levels increased 4-fold between 1 and 15 days, remained stable between 15 and 30 days, and decreased 2-fold between 30 and 60 days. These changes were fully suppressed by in vivo treatment with actinomycin D, an inhibitor of gene transcription. In vitro nuclear transcription assays showed that the rate of transcription of the insulin receptor gene increased 2-fold between 1 and 30 days. Insulin receptor concentration in liver membrane fractions did not exactly parallel insulin receptor mRNA levels since it increased by 20-30% from 1 to 10 days and decreased 2-fold from 10 to 60 days. During the suckling-weaning transition, insulin receptor mRNA level decreased 2-fold in rats weaned onto a high carbohydrate diet but remained unchanged in rats weaned onto a high fat diet. Throughout postnatal life, an inverse relationship was observed between liver insulin receptor mRNA and plasma insulin levels. These results show that transcriptional changes in insulin receptor gene expression occur postnatally and suggest that such changes may be insulin-related.

Vanadate treatment of diabetic rats reverses the impaired expression of genes involved in hepatic glucose metabolism: effects on glycolytic and gluconeogenic enzymes, and on glucose transporter GLUT2.

The trace element vanadium is a potent insulinomimetic agent in vitro. Oral administration of vanadate to rats made diabetic by streptozotocin (45 mg/kg i.v.) caused a 65% fall in plasma glucose levels without modifying low insulinemia. We studied whether the hypoglycemic effect of vanadate was associated with altered expression of genes involved in key steps of hepatic glucose metabolism. Glucokinase (GK) and L-type pyruvate kinase (L-PK) mRNA levels were decreased respectively by 90% and 70% in fed diabetic rats, in close correlation with changes in enzyme activities. Eighteen days of vanadate treatment partially restored GK mRNA and activity (40% of control levels), and totally restored L-PK parameters. In contrast to the glycolytic enzymes, mRNA levels and activity of the gluconeogenic enzyme, phosphoenolpyruvate carboxykinase (PEPCK) were increased (15- and 2-fold, respectively) in fed diabetic rats. Vanadate treatment normalized both PEPCK mRNA and activity in diabetic rat liver. The 2-fold increase in liver glucose transporter (GLUT2) mRNA and protein, produced by diabetes, was also corrected by this treatment. In conclusion, oral vanadate given to diabetic rats induces a shift of the predominating gluconeogenic flux, with subsequent high hepatic glucose production, into a glycolytic flux by pretranslational regulatory mechanisms.

[Regulation of insulin receptor expression and its gene]. / Régulation de l'expression du récepteur de l'insuline et de son gène.

The insulin receptor is a membrane macromolecule whose expression on the cell surface is essential for cell sensitivity to insulin. Current knowledge on the regulation of expression of the insulin receptor and its gene in human and animal cells is presented. Although ubiquitously distributed, the insulin receptor and its messenger RNA (mRNA) are mainly expressed in metabolically active cells such as hepatocytes and adipocytes. Two receptor isoforms, generated by alternative splicing of exon 11, have been identified. Isoform B (exon 11+) predominates in liver and adipocytes, and isoform A (exon 11-) in brain, spleen and leukocytes. In vivo and in several cell models, the expression of the insulin receptor and/or its mRNA is under positive regulation by glucocorticoid hormones and negative regulation by insulin. Glucocorticoid hormones stimulate receptor gene transcription and receptor protein synthesis. Insulin stimulates receptor protein degradation and, in certain cell types, decreases receptor mRNA level. Vanadate (an insulinomimetic agent) corrects, in vivo, the hyperexpression of the liver receptor observed in experimental insulinopenic diabetes, but its effects on receptor expression in vitro are complex and vary with the cell type. In vivo the insulin receptor and/or its mRNA are expressed early in fetal development with a high level, in liver, of isoform A. Maximal expression is reached at the end of gestation and then decreases after birth. In several cell models, receptor protein and/or mRNA expression is affected by cell growth and/or differentiation. Several cis- and trans-acting factors regulating the expression of the human insulin receptor gene and its response to glucocorticoid hormones have been identified.

Effects of STZ-induced diabetes and fasting on insulin receptor mRNA expression and insulin receptor gene transcription in rat liver.

Insulinopenic states in rodents are known to cause an increase in the number of hepatic insulin receptors. To determine if this change is related to an abnormality in insulin receptor gene expression, insulin receptor binding, insulin receptor mRNA levels, and insulin receptor gene transcription rates have been measured in livers from rats rendered hypoinsulinemic by STZ administration (65 mg/kg) or fasting. In the two groups of experimental rats, insulin binding to liver plasma membranes was increased (approximately 40 and 25%, respectively) relative to control, normoinsulinemic animals. Northern blot analysis of either total or poly (A)+ RNA from livers of hypo- and normoinsulinemic rats revealed two major insulin receptor mRNA species of 9.5 and 7.5 kbs. In hypoinsulinemic rats, insulin receptor mRNA levels were increased > or = 10-fold, with similar effects on the two mRNA species. The effects of STZ administration and fasting on insulin receptor binding and insulin receptor mRNA levels were fully reversed by insulin treatment or refeeding, respectively. Injection of ACT D, an inhibitor of gene transcription, decreased insulin receptor mRNA levels by > or = 80% in control and diabetic rats and suppressed the overexpression of mRNA seen in diabetic rats. In vitro nuclear transcription assays showed that the rate of transcription of the insulin receptor gene was increased 2-fold in STZ-induced diabetic rats and fasted rats relative to control animals. Taken together, these results suggest that the upregulation of the insulin receptor induced by chronic insulinopenia results, at least in part, from an increase in insulin receptor gene transcription.

Ligand-mediated internalization of glucagon receptors in intact rat liver.

The ligand-induced internalization of the hepatic glucagon receptor has been studied in rats in vivo using cell fractionation. Injection of glucagon (11 nmol/100 g BW) led to a 2- to 3-fold increase in glucagon-binding activity in Golgi-endosomal (GE) fractions along with a 10-20% decrease in binding activity in plasma membrane (PM) fractions. These changes were time and dose dependent, reaching a maximum by 12-24 min and undergoing reversal in 2 h. Glucagon injection also caused a 20% decrease in glucagon binding to the total particulate fraction, which did not occur when binding was measured in the presence of the detergent octylglucoside. The change in glucagon-binding activity in PM and GE fractions resulted mainly from a change in receptor number; affinity remained unaffected (apparent Kd, 0.5 and 5 nM, respectively). A 5- to 10-fold increase in the glucagon content of GE fractions was observed in glucagon-treated rats. Neither the distribution of PM and Golgi marker enzymes nor that of the asialoglycoprotein receptor was affected by glucagon treatment. Regardless of glucagon treatment, glucagon receptors in GE fractions were less sensitive to GTP than receptors in PM fractions with respect to both inhibition of steady state binding and dissociation of prebound ligand. On sodium dodecyl sulfate-polyacrylamide gel electrophoresis, glucagon-receptor complexes formed in PM and GE fractions and subsequently cross-linked showed the same apparent mol wt (57 kilodaltons). In addition, they were identically sensitive to N-glycanase treatment, with two major species of lower mol wt generated. However, only cross-linked complexes associated with PM fractions showed detectable GTP sensitivity. GE fractions displayed a GTP-sensitive adenylate cyclase activity that was about 12 times lower than that of PM fractions. In both fractions, activity was stimulated by the addition of forskolin (8-fold) and, to a lesser extent, glucagon (3-fold). In vivo glucagon treatment led to an increase in activity in GE, but not PM, fractions. These results are consistent with the view that upon acute occupancy, hepatic glucagon receptors are rapidly and specifically internalized along with their ligand. During this process, receptor retained structural integrity and uncouple, albeit partially, from other components of the adenylate cyclase system.

Uptake of injected 125I-ricin by rat liver in vivo. Subcellular distribution and characterization of the internalized ligand.

Subcellular-fractionation techniques were used to characterize the endocytic pathway followed by ricin in rat liver in vivo and tentatively identify the site(s) at which the ricin interchain disulphide bridge is split. After injection of 125I-ricin, hepatic uptake of radioactivity was maximum at 30 min (40% of injected dose). At 5 min, about 80% of the radioactivity in the homogenate was recovered in the microsomal (P) fraction, but later on the recovery of the radioactivity in the mitochondrial-lysosomal (ML) fractions progressively increased (50% at 30 min) at the expense of that in the P fraction. Subfractionation of the P and ML fractions on analytical sucrose-density gradients revealed a time-dependent translocation of the radioactivity from low- to high-density endocytic structures, with median relative densities at 5 and 60 min of about 1.15 and 1.16 (P fraction) and 1.19 and 1.22 (ML fraction) respectively. The late distribution of the radioactivity in the ML fraction was similar to that of the lysosomal marker acid phosphatase. Studies with co-injected lactose and mannan showed that ricin was internalized mainly via the mannose receptor. In the presence of mannan, the late recovery of radioactivity in the ML fraction was decreased, and the distribution of the radioactivity associated with the P fraction was shifted toward lower densities (median relative density 1.13), indicating a different pathway of endocytosis. Analysis of the radioactivity associated with the ML and S fractions by SDS/PAGE revealed a time-dependent increase in the amount of intact A- and B-chains and low-molecular-mass products. When ML fractions containing partially processed ricin were incubated at 37 degrees C at pH 5 or at pH 7.2 in the presence of ATP, only low-molecular-mass products were generated. We conclude that internalized ricin associates with endocytic structures whose size and density of equilibration increase with time, and that, although detectable in these structures, reduction of the ricin interchain disulphide bridge occurs to a large extent in the cytosol.

Role of acidic subcellular compartments in the degradation of internalized insulin and in the recycling of the internalized insulin receptor in liver cells: in vivo and in vitro studies.

Upon interaction with liver cells, insulin is internalized along with its receptor into nonlysosomal endocytic structures termed endosomes. In this work, the biochemical evidence supporting the role of endosomal acidity in the degradation of internalized insulin and in the recycling of the internalized insulin receptor is described. Treatment of rats by chloroquine and/or quinacrine, two acidotropic drugs, increases by 5-10 fold the amount of endogenous insulin associated with endosomal fractions and, in rats injected by 125I-labeled or native insulin, the endosomal uptake of these ligands at late times after injection. With 125I-insulin, these drugs inhibit the degradation of internalized hormone as judged on physical, biological and immunological criteria. Chloroquine and quinacrine treatment also increases the insulin receptor content of endosomal fractions and, in rats injected by native insulin, the ligand-induced accumulation of receptors in endosomal fractions at late times after injection. Subfractionation of endosomal fractions on Percoll gradients shows that chloroquine treatment shifts the distribution of both insulin and the insulin receptor towards higher densities, the receptor shift being slightly more pronounced in insulin-injected rats. Incubation of isolated endosomes containing internalized insulin at 30-37 degrees C results in a rapid degradation of this ligand, with a maximal at pH 5-6. Addition of ATP, by decreasing the endosomal pH, stimulates insulin degradation above pH 7, whereas addition of chloroquine and quinacrine, by elevating endosomal pH, exerts opposite effects. These data indicate that endosomal acidity is required for optimum degradation of internalized insulin within endosomes and recycling of the internalized receptor.